Optimized directionless optical add/drop module systems and methods

ABSTRACT

The present disclosure provides optimized configurations for a directionless reconfigurable optical add/drop multiplexer application. The present invention includes an add module with improved optical signal-to-noise through placing amplifiers prior to a multi-cast optical switch. The present invention includes various drop module configurations utilizing distributed gain, channel selective filters, and bi-directional configurations to reduce power consumption and complexity. Additionally, the present invention includes an integrated broadcast and select architecture.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present non-provisional patent application is a continuation-in-part of co-pending U.S. patent application Ser. No. 12/268,817, filed on Nov. 11, 2008, and entitled “SIGNAL DISTRIBUTION MODULE FOR A DIRECTIONLESS RECONFIGURABLE OPTICAL ADD/DROP MULTIPLEXER,” which is a continuation-in-part of co-pending U.S. patent application Ser. No. 12/234,049, filed on Sep. 19, 2008, and entitled “MODULAR ADD/DROP MULTIPLEXER INCLUDING A WAVELENGTH SELECTIVE SWITCH,” which is a divisional of U.S. Pat. No. 7,499,652, issued on Mar. 3, 2009, and entitled “MODULAR ADD/DROP MULTIPLEXER INCLUDING A WAVELENGTH SELECTIVE SWITCH,” which is a divisional of U.S. Pat. No. 7,308,197, issued on Dec. 11, 2007, and entitled “MODULAR ADD/DROP MULTIPLEXER INCLUDING A WAVELENGTH SELECTIVE SWITCH,” which claims the benefit of priority of U.S. Provisional Patent Application Nos. 60/444,284 and 60/443,898, both filed on Jan. 31, 2003, the contents of all of which are incorporated in full by reference herein.

FIELD OF THE INVENTION

The present invention relates generally to optical communication systems. More specifically, the present invention relates to optimized add/drop modules for a directionless reconfigurable optical add/drop multiplexer (ROADM).

BACKGROUND OF THE INVENTION

In optical communication systems, optical signals are transmitted along an optical communication path, such as an optical fiber. Early optical communication systems deployed a single optical transmitter at a nominal wavelength of light at one end of an optical fiber link and a single optical receiver at the other end of the optical fiber link to detect the incoming optical signals. More recently, wavelength division multiplexed (WDM) systems have been deployed in which multiple wavelengths of light are combined onto a single optical fiber in order to increase the information carrying capacity of the optical communication network.

In a WDM system, multiple optical transmitters feed optical signals to an optical multiplexer that is provided at one end of an optical fiber link and an optical demultiplexer is provided at the other end of the optical fiber link to separate the combined optical signal into its constituent optical signals at corresponding wavelengths of light. Often, however, optical communication network configurations require that given wavelengths of light be selected or “dropped” from the combined optical signal prior to reaching the optical demultiplexer at the termination point of the optical fiber link. In addition, optical signals at the “drop” wavelength of light or other wavelengths of light are often required to be added prior to the termination point of the optical fiber link. Accordingly, optical add/drop multiplexers have been developed that add/drop optical signals at given wavelengths of light, while permitting optical signals at other wavelengths of light to pass to the add/drop or termination points.

A conventional optical add/drop multiplexer is described, for example, in U.S. Pat. No. 6,459,516, the contents of which are incorporated in full by reference herein. This optical add/drop multiplexer flexibly accommodates a relatively large number of added/dropped optical signals or channels. The channels that are added/dropped are fixed, however, and the optical add/drop multiplexer is not remotely reconfigurable.

An alternative optical add/drop multiplexer is a select optical add/drop multiplexer (SOADM), commercially available from CIENA Corporation of Linthicum, Md. As illustrated in FIG. 1, the SOADM receives incoming optical signals through an optical amplifier 110. The optical signals are passed from the optical amplifier 110 to a power splitter or coupler 120, which supplies a first portion of each incoming optical signal to a reconfigurable blocking filter (RBF) 130 and a second portion of each incoming optical signal to a pre-booster amplifier 160 and, subsequently, a router 180. The router 180 separates the second portion of each incoming optical signal into separate channel groups, one of which is passed through a segment of dispersion compensating fiber (DCF) 121, and then to an optical amplifier USA 197. The channel group is then fed to a channel group demultiplexer including a 1×8 splitter 119, which supplies the channel group on each of eight outputs. The splitter 119 is a conventional power splitter, such that the signal strength of each output is attenuated to about ⅛^(th) the power of the input. Channel filters (not illustrated) are coupled to each output of the splitter 119 to select individual channels from each output and supply the demultiplexed channels to corresponding receivers (not illustrated).

Added channels are supplied from transmitters (not illustrated) to an 8×1 combiner 117 through an amplifier 115 and a router 195. At the output of the router 195, the added channel group is passed through an optional segment of DCF 190 and amplified by an amplifier 170. The added channel group is the combined with the channels output from the RBF 130 by a coupler 140, and the resulting WDM signal is output through an amplifier 150.

In operation, the RBF 130 is configured to block the channel group selected by a port 161 of the router 180, while the remaining channel groups pass through. Although non-selected wavelengths of are also supplied to the router 180, no optical demultiplexing elements or optical receivers are provided to sense the non-selected wavelengths of light. The added channels are typically at the same wavelength of light as the blocked channels in order to prevent interference between those optical signals passed through the RBF 130 and those optical signals that are added. Alternatively, the added channels may be different from any of the pass through channels.

Moreover, the RBF 130 may be reconfigured such that a different channel group is blocked. In which case, optical demultiplexers must be added to a different port or slot of the router 180, for example. Since the optical add/drop multiplexers are often deployed in remote locations, service personnel must travel to the optical add/drop multiplexer site(s) and physically attach the channel group optical demultiplexer to a new output port of the router 180.

Alternatively, the RBF 130 may be replaced with a wavelength selective switch (WSS) 210, as illustrated in FIG. 2. WSSs are known components that are coupled to multiple input lines and output lines, and selectively block optical signals on a per wavelength basis. In this instance, the WSS 210 is coupled to input lines 209, 213, and 215, and output lines 222, 225, and 226. The operation of the routers and group demultiplexers is similar to that described above with regard to FIG. 1. However, as illustrated in FIG. 2, additional routers may be provided, each one coupled to a corresponding one of the input lines or output lines. However, the WSS-based optical add/drop multiplexer illustrated in FIG. 2 suffers from disadvantages similar to those described above with regard to FIG. 1. Namely, any reconfiguration of the WSS 210 resulting in a change in the wavelengths of light to be added/dropped requires physically coupling the channel group optical demultiplexers to a different router output port.

ROADMs are the key technology for the next generation of dense wavelength division multiplexing (DWDM) systems. These ROADMs allow for the automated rearrangement of wavelengths of light on the multichannel optical fibers entering and leaving optical network nodes. For a high-degree optical network node, with a degree number of up to 8, for example, directionless ROADMs are preferred because they may route any wavelength of light on any optical fiber (or from any direction) to any given transceiver entirely in the optical domain.

As is described in greater detail herein below, in existing ROADM designs, erbium-doped fiber amplifier (EDFA) arrays with fixed gains or output powers are utilized in order to satisfy a worst case scenario, even though there are only M (e.g. 8 or 16) channels to be dropped for a given modular design. This is not a cost effective solution. Each EDFA is over designed to support the worst case scenario, when all of the wavelengths of light or channels are fully populated. More than 40% of the associated cost is attributed to the pump lasers for the individual EDFAs. In order to simplify the design of the signal distribution modules utilized in directionless ROADM applications, as well as shrink their size and lower their cost, the present invention provides a novel configuration that takes full advantage of type A/type B+ N×M multi-cast switches and the advanced EDFA array design with planar lightwave circuit (PLC)-based tunable pump splitters.

BRIEF SUMMARY OF THE INVENTION

In an exemplary embodiment, an add side of a directionless optical add/drop module includes a multi-cast switch having a plurality of input ports and a plurality of output ports; a plurality of optical amplifiers connected to the plurality of input ports of the multi-cast switch, wherein the plurality of optical amplifiers form an optical amplifier array; and a plurality of tunable filters connected to the plurality of input ports of the multi-cast switch. Optionally, the plurality of tunable filters disposed between the plurality of input ports of the multi-cast switch and the plurality of optical amplifiers. Alternatively, the plurality of optical disposed between the plurality of input ports of the multi-cast switch and the amplifiers plurality of tunable filters. The plurality of optical amplifiers may include a plurality of erbium-doped fiber amplifiers, and wherein the plurality of erbium-doped fiber amplifiers form an erbium-doped fiber amplifier array. The erbium-doped fiber amplifier array may utilize a shared pump laser.

In another exemplary embodiment, a drop side of a directionless optical add/drop module includes a multi-cast switch having a plurality of input ports and a plurality of output ports; a plurality of optical amplifiers connected to the plurality of input ports of the multi-cast switch, wherein the plurality of optical amplifiers form an optical amplifier array; and a plurality of tunable filters connected to the plurality of output ports of the multi-cast switch. The plurality of optical amplifiers may include a plurality of erbium-doped fiber amplifiers, and wherein the plurality of erbium-doped fiber amplifiers form an erbium-doped fiber amplifier array. The erbium-doped fiber amplifier array utilizes a shared pump laser. The drop side may further includes a second plurality of optical amplifiers connected to the plurality of output ports of the multi-cast switch, wherein the second plurality of optical amplifiers form a second optical amplifier array, and wherein the optical amplifier array and the second optical amplifier array are configured to provide distributed gain. Optionally, the second optical amplifier array is disposed between the multi-cast switch and the plurality of tunable filters. Alternatively, the plurality of tunable filters include a first plurality of tunable filters and a second plurality of tunable filters, and wherein the second optical amplifier array is disposed between the first plurality of tunable filters and the second plurality of tunable filters. The drop side may include a first plurality of optical circulators connected between the optical amplifier array and the multi-cast switch; and a second plurality of optical circulators connected between the first plurality of tunable filters and the second optical amplifier array. Alternatively, the drop side includes a plurality of channel selective filters connected to inputs of the optical amplifier array. Here, the drop side may further include a first plurality of optical circulators connected between the optical amplifier array and the multi-cast switch; and a second plurality of optical circulators connected to outputs of the plurality of tunable filters.

In yet another exemplary embodiment, an integrated directionless optical add/drop module includes a drop side with a broadcast and select architecture; and an add side with the broadcast and select architecture; wherein the broadcast and select architecture includes turning an amplifier on in a path to connect a particular transceiver to a particular degree while also turning a plurality of amplifiers connecting the transceiver to other degrees off. The drop side and the add side include a plurality of splitters, a plurality of combiners, a plurality of tunable filters, and a plurality of optical amplifiers. The drop side includes the plurality of splitters connected to the plurality of tunable filters, the tunable filters connected to the plurality of optical amplifiers, the plurality of optical amplifiers connected to the plurality of combiners, and a second plurality of tunable filters connected to outputs of the plurality of combiners; and wherein the add side includes the plurality of splitters connected to the plurality of optical amplifiers, the plurality of optical amplifiers connected to the plurality of tunable filters, and the plurality of tunable filters connected to the plurality of combiners. The plurality of optical amplifiers may include an amplifier array of semiconductor optical amplifiers.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated and described herein with reference to the various drawings of exemplary embodiments, in which like reference numbers are used to denote like system components/method steps, as appropriate, and in which:

FIG. 1 is a schematic diagram illustrating a conventional optical add/drop multiplexer design incorporating a RBF;

FIG. 2 is a schematic diagram illustrating a conventional optical add/drop multiplexer design incorporating a WSS;

FIG. 3 is a schematic diagram illustrating a WSS-based optical add/drop multiplexer consistent with an aspect of the present invention;

FIGS. 4( a)-4(c) are schematic diagrams illustrating examples of tunable optical demultiplexers consistent with an aspect of the present invention;

FIG. 5 is a schematic diagram illustrating a WSS-based optical add/drop multiplexer consistent with a further aspect of the present invention;

FIG. 6 is a schematic diagram illustrating a WSS-based optical add/drop multiplexer including a multi-cast switch consistent with a further aspect of the present invention;

FIGS. 7( a) and 7(b) are schematic diagrams illustrating examples of directionless ROADMs consistent with an aspect of the present invention;

FIGS. 8( a) and 8(b) are schematic diagrams illustrating examples of N×M multi-cast switches consistent with an aspect of the present invention;

FIG. 9 is a schematic diagram illustrating a signal distribution module employing an N×M multi-cast switch and a conventional EDFA array consistent with an aspect of the present invention;

FIG. 10 is a schematic diagram illustrating a 4-EDFA array design utilizing 1×4 tunable splitters;

FIG. 11 is a schematic diagram illustrating a signal distribution module incorporating an EDFA array coupled to a shared pump laser and tunable splitter in order to accommodate the variable insertion losses of an N×M multi-cast switch;

FIG. 12 is a schematic diagram illustrating an implementation for a directionless add/drop module with a “drop” side and an “add” side;

FIGS. 13 a-13 b are schematic diagrams illustrating the add side in FIG. 12 with different placements of the EDFAs;

FIGS. 14 a-14 b are schematic diagrams illustrating the drop side in the directionless add/drop module of FIG. 12 is illustrated with distributed gain;

FIG. 15 is a schematic diagram illustrating the drop side in the directionless add/drop module of FIG. 12 with channel selective filters;

FIGS. 16 a-16 b are schematic diagrams illustrating a bi-directional design for the directionless add/drop module of FIG. 12; and

FIGS. 17 a-17 b are schematic diagrams illustrating an integrated design directionless add/drop module with a broadcast and select architecture.

DETAILED DESCRIPTION OF THE INVENTION

Consistent with the optical communication system of the present invention, tunable optical demultiplexers have been provided in WSS-based optical add/drop multiplexers. The tunable optical demultiplexers have been modular, and thus allow the optical add/drop multiplexers to be readily expandable and facilitate flexible optical add/drop capabilities, whereby a channel present on any input line to the WSS may be dropped and supplied to one or more desired output lines of the tunable optical demultiplexers. Similar flexibility has been achieved on the add-side of the WSS. Moreover, the optical demultiplexers and the WSS have been remotely configurable, thus obviating the need to manually disconnect and connect the optical demultiplexers to a router. Multi-cast switches have been provided that permit the same channel, for example, to be provided to one or more output lines of the optical add/drop multiplexer, such that a copy of the channel may carry working traffic, while another copy of the channel may carry protection traffic. As a result, 1+1 and 1:N optical layer protection has been achieved.

FIG. 3 illustrates a WSS-based optical add/drop multiplexer 302 consistent with an aspect of the present invention. The optical add/drop multiplexer 302 includes a WSS 315 having a plurality of input ports 315-1 to 315-n each coupled to a respective one of a plurality of input optical communication paths 312-1 to 312-n. Each input optical communication path 312-1 to 312-n may be coupled to an optical amplifier, such as the optical amplifier 305 coupled to the first input optical communication path 312-1, for example. The input optical communication paths 312-1 to 312-n each include commercially available optical fiber, for example, and the optical amplifier 305 is a conventional EDFA, for example. Input optical signals, each at a particular wavelength of light, and collectively constituting a WDM signal, propagate along the first input optical communication path 312-1. Other WDM signals likewise propagate along the other input optical communication paths 312-2 to 312-n.

As further illustrated in FIG. 3, a power splitter 310-1, including, for example, a fiber optic coupler, tap, or other suitable optical component, is coupled to the first input optical communication path 312-1. Likewise, power splitters 310-2 to 310-n are coupled to the other respective input optical communication paths 312-2 to 312-n. A first portion of the WDM signal propagating on the first input optical communication path 312-1 is output from the power splitter 310-1, through an optional dispersion compensating module 330 and an optional optical amplifier 334 to an input port 332-3 of a tunable optical demultiplexer 332. Selected channels (i.e. optical signals at specific wavelengths of light) are respectively output from corresponding ones of the outputs 332-1. Other channels, however, are output through an expansion port 332-2, and fed through an optional optical amplifier 336 to an input port 338-3 of a tunable optical demultiplexer 338. These other channels are then separated and supplied to corresponding ones of first outputs 338-1 and to receivers discussed in greater detail herein below, but a second output 338-2 is a supplemental port not connected to any receivers.

Initially deployed WDM optical communication systems are not fully populated with a maximum number of channels, as capacity requirements are typically lower at first but increase over time. Thus, a full complement of optical demultiplexers may not be required at first, but rather a smaller number is sufficient to drop the relatively low numbers of channels typically present when a WDM optical communication system is first deployed. Accordingly, a limited number of tunable optical demultiplexers are often provided at system turn-up, but each has a supplemental port, not connected to receiver circuits, such that additional tunable optical demultiplexers may be attached later on as capacity requirements grow. Large optical demultiplexer circuits need not be installed early in a product life cycle. Instead, modular tunable optical demultiplexers are added incrementally on an as-needed basis, resulting in substantial cost savings.

Returning to FIG. 3, the optical demultiplexer 332 is tunable because the wavelengths of light selected for output at each port may be tuned or adjusted in response to a control signal. For example, an optical signal having wavelength λ₁ may initially be output from one of the drop ports 332-1 of the flexible optical demultiplexer 332 (i.e. the N-port drop module). In response to a control signal, however, a different optical signal having wavelength λ₉ may be output.

Control information is carried by an optical service channel present on one of the input optical communication paths 312-1, for example. An additional optical demultiplexer 360, such as an optical filter, selects the optical service channel, which is typically at a wavelength of light that is different than the other information carrying wavelengths of light of the WDM signal. As is generally understood, the optical service channel often carries optical system or optical network-related information, such as diagnostic, monitoring, as well as control information. The optical service channel is output from the optical demultiplexer 360 and supplied to a control circuit 350, which converts the optical service channel into corresponding electrical signals in a known manner, and generates appropriate control signals in response to the received optical service channel. The control signals may be supplied to each of the tunable optical demultiplexers 332 and 338, for example.

Adding channels is similar to dropping them, but in reverse. A plurality of conventional tunable optical transmitters 341-1 to 341-n are coupled to respective ones of the inputs or add ports 340-1 of a combiner or tunable optical multiplexer 340. The optical multiplexer 340 also has a supplemental input or expansion port not coupled to an optical transmitter to accommodate further combiners as system capacity requirements increase. Optical signals generated by the transmitters 341-1 to 341-n are typically each at a different wavelength of light and are supplied to the output 340-3, through an optional optical amplifier 342, and to an input or expansion port 344-2 of the combiner 344. The combiner 344 also receives additional optical signals, each at a respective wavelength of light, on respective ones of the add ports or inputs 344-1 from optical transmitters (not illustrated), similar to the optical transmitters 341-1 to 341-n. The optical signals supplied through the expansion port 344-2 and add ports 344-1 are combined onto the output 344-3 and fed to the combiner 320-1, through an optional optical amplifier 346 and an optional dispersion compensating element 348. The optical combiner 320-1 combines these optical signals with signals output from the WSS 315 through a port 316-1 onto the output optical communication path 313-1, through an optional optical amplifier 325. The optical amplifier 325, as well as other optical amplifiers described herein, are provided to offset any attenuation of the optical signals passing through the WSS 315, as well as those added and dropped by the optical add/drop multiplexer 302.

Moreover, additional combiners, similar to the combiners 340 and 344, may be coupled in a similar manner to the combiners 320-2 to 320-n to facilitate the coupling or combining of the optical signals output from the WSS output ports 316-2 to 316-n onto further output optical communication paths 313-2 to 313-n. The tunable optical multiplexers or combiners 340 and 344 may have a structure similar to the tunable optical; demultiplexers 332 and 338, but are connected in reverse, such that the add ports input signals instead of outputting them, and the outputs of the combiners 340 and 344 supply signals instead of receiving them.

Although the tunable optical demultiplexers are illustrated for combining optical signals in the various embodiments of the present invention, other combiners may also be utilized. For example, conventional passive optical combiners, or other suitable optical components, that combine optical signals may be used in conjunction with the systems and methods of the present invention. It should be noted that passive optical combiners typically cost less than tunable optical demultiplexers.

FIGS. 4( a)-4(c) illustrate examples of tunable optical demultiplexers consistent with an aspect of the present invention. It should be understood that any of the tunable optical demultiplexers may have a construction as illustrated in one or more of FIGS. 4( a)-4(c). In the example illustrated in FIG. 4( a), the tunable optical demultiplexer includes a 1×N+1 splitter 430 having an input 425 (e.g. corresponding to an input 332-1) that receives signals supplied from the splitter 310-1 (FIG. 3), for example. The splitter 430 has N+1 outputs, N of which supply attenuated portions of the input optical signal to corresponding tunable filters 432-1 to 432-n, each of which is controlled in accordance with information contained in, or in response to, the optical service channel to select an optical signal at a desired wavelength of light. The filtered optical signals are then supplied to corresponding receivers 450-1 to 450-n. The N+1th output, however, corresponds to the supplemental or expansion output to facilitate modular expansion of the optical demultiplexing capabilities of the optical add/drop multiplexer in an inexpensive manner.

Referring to FIG. 4( b), the tunable filters 480-1 to 480-n are cascaded, whereby the optical signals fed through the input 425 are first supplied to the tunable filter 480-1, which reflects, for example, one of the input signals, but passes the remaining signals. The remaining signals are then input to the tunable filter 480-2, which selects another optical signal in a similar fashion as the tunable filter 480-1. The remaining signals are passed from one tunable filter to the next, and, at each filter, a different channel is selected. The selected channels are, in turn, fed to corresponding receivers 450-1 to 450-n. If any channels are not selected by the tunable filters 480-1 to 480-n, they are fed to a supplemental output 452 for propagation to another tunable optical demultiplexer, as noted above. The tunable filters 480-1 to 480-n are controlled in response to the optical service channel.

As illustrated in FIG. 4, an integrated N-port drop module including tunable filters configured as illustrated in either FIG. 4( a) or FIG. 4( b) may also be provided. In which cases, the tunable filters and other necessary components are integrated into a single component housing 490. As in other examples, a supplemental port 452 is also included.

The tunable filters illustrated above are commercially available from JDS Uniphase, Optoplex, or Dicon, for example. The integrated N-port drop module illustrated in FIG. 4( c) is also commercially available from JDS Uniphase, for example.

As noted previously, the exemplary embodiment illustrated in FIG. 3 provides a cost effective, yet flexible, approach to expanding a WSS-based optical add/drop multiplexer. An alternative exemplary embodiment will next be described with reference to FIG. 5 illustrating an optical add/drop multiplexer 510 consistent with a further aspect of the present invention.

As with the optical add/drop multiplexer 302 illustrated in FIG. 3, the exemplary embodiment illustrated in FIG. 5 also includes a WSS 315, as well as a plurality of input and output optical communication paths and splitters 310-1 to 310-n. In addition, the optical add/drop multiplexer 510 illustrated in FIG. 5 similarly includes combiners 320-1 to 320-n and output optical communication paths, as discussed above in regard to FIG. 3. The operation of these elements is as before.

The optical add/drop multiplexer 510, however, differs from the optical add/drop multiplexer 302 described previously in that the tunable optical demultiplexers and multiplexers with supplemental or expansion ports are replaced with an additional splitter 520 and combiner 534, for example. Tunable demultiplexers 526 and 528 are also typically included. Although each of the tunable elements 526, 528, 530 and 532 are illustrated without supplemental ports, such supplemental ports may be provided, if necessary, and further tunable optical demultiplexers and multiplexers may attached in a manner similar to that described above in regard to FIG. 3.

The operation of optical add/drop multiplexer 510 will next be described. Optical signals input from the splitter 310-1 and dispersion compensation element 330, for example, are supplied to an optical splitter 520, typically a power splitter, through an input 520-1 which, in turn, supplies portions of the received optical signals to each of the outputs 520-2 to 520-4. The outputs 520-2 and 520-4 are respectively coupled, through optical amplifiers 522 and 524, to tunable optical demultiplexers 526 and 528, which separate the optical signals input thereto in response to the optical service channel carried on an input optical communication path, for example, in a manner similar to that described above with respect to FIGS. 3 and 4( a)-4(c). As a result, desired dropped channels are output from the drop ports illustrated in FIG. 5. It should be understood that additional splitters are coupled to the splitters 310-2 to 310-n, and additional tunable optical demultiplexers are coupled to these additional splitters in a manner similar to that discussed above in regard to the splitter 520 and tunable optical demultiplexers 526 and 528.

The optical splitter 520 also has a supplemental port or output 520-3 not coupled to a tunable optical demultiplexer. The supplemental output 520-3 may accommodate an additional tunable optical demultiplexer, should one be needed in light of increased capacity needs requiring that additional channels be dropped. Upon initial deployment, however, when an optical communication system is not fully populated with WDM signals, as noted above, the supplemental output 520-3 of the splitter 520, for example, allows for modular expansion and a cost-effective upgrade path.

As further illustrated in FIG. 5, added channels are supplied to the tunable optical multiplexers or combiners 530 and 532 in a manner similar to that described above with respect to the tunable optical multiplexers 340 and 344. In response to the optical service channel, the tunable optical multiplexers 530 and 532 combine signals supplied thereto typically onto a single output, which is coupled to corresponding inputs 534-1 and 534-3 or the combiner 534. The signals output from the tunable optical multiplexers 530 and 532 are then further combined onto an output 534-4 of the combiner 534. These signals are then optionally amplified by an amplifier 536, passed though optional dispersion compensating element 538, and fed to an output optical communication path by a combiner 320-1.

The combiner 534 has a supplemental input not coupled to a tunable optical multiplexer, for expansion purposes and accommodating modular growth.

Further combiners, similar to the combiner 534, are also coupled to corresponding ones of the combiners 320-2 to 320-n. Also, an additional tunable optical multiplexer may be coupled to such further combiners in a similar fashion as that described above in regard to the tunable optical multiplexers 530 and 532.

The optical add/drop multiplexers discussed above are advantageous in that each may provide a cost-effective growth path for system operators and users. Moreover, these optical add/drop multiplexers provide substantial flexibility by permitting the dropping of any channel present on a particular input optical communication path. Further, any channel may be added to a particular output optical communication path. Nevertheless, the above-described exemplary embodiments are limited in that each tunable optical demultiplexer and multiplexer is dedicated either to a particular input or output optical communication path. Greater system flexibility may be achieved when the tunable optical demultiplexers and multiplexers may be coupled to any input or output optical communication path of the WSS, as discussed in greater detail below with respect to FIG. 6.

The optical add/drop multiplexer 610 illustrated in FIG. 6 is similar to the optical add/drop multiplexer 510 illustrated in FIG. 5. Instead of providing splitters, such as the splitter 520, however, being coupled to a bank of optical amplifiers and tunable optical demultiplexers, a plurality of splitters 612-1 to 612-n are provided, each of which is coupled to a corresponding one of the splitters 310-1 to 310-n. Each of the splitters 612-1 to 612-n typically has an output coupled, through a respective one of the amplifiers 618-1 to 618-n, to a multi-cast optical switch 624 (such as an 8×8 multi-cast optical switch commercially available from Lynx PhotoniNEL or Enablence, for example). On the add side, a multi-cast optical switch 634 is provided for coupling tunable optical multiplexers to desired output optical communication paths.

In operation, a portion of the WDM signal present on input optical communication path 312 is passed through an optional dispersion compensating element 330-1 and supplied to a splitter 612-1. The splitter 612-1 typically includes a plurality of outputs, one of which supplies a further portion of the optical signals to the multi-cast switch input 624-1 via an amplifier 618-1. The multi-cast optical switch 624 (illustrated as an M×M optical switch, where M is an integer, e.g. 8) acts to further power split the signal input thereto, but supplies the split signals to selected outputs, instead of all of its outputs (as in the case of a conventional 1×N splitter.) Thus, for example, signals appearing on the input 624-1 may be supplied to the output 624-5 and other selected outputs, but not every output. In which case, since the output 624-5 is coupled to the tunable optical demultiplexer 626, optical signals originating on the input optical communication path 312-1 are only supplied to the tunable optical demultiplexer 626, as well as other selected tunable optical demultiplexers, for example, the tunable demultiplexer 628 through the output 624-7. If desired, all tunable optical demultiplexers are coupled to the multi-cast optical switch 624. Receiver circuits 696-1 to 696-n may be coupled to the respective ports or outputs of the tunable optical demultiplexer 626. Similar receiver circuits are coupled to the drop ports or outputs of tunable optical demultiplexer 628, as well as any other tunable optical demultiplexer coupled to the multi-cast switch 624.

As further illustrated in FIG. 6, other input optical communication paths 312-2 to 312-n are respectively coupled to the multi-cast switch inputs 624-2 to 624-n via corresponding ones of the splitters 312-2 to 312-n, optional dispersion compensating elements 330-2 to 330-n, and optional amplifiers 618-2 to 618-n. Accordingly, the multi-cast switch 624 may serve to couple any input optical communication path to any tunable optical demultiplexer.

The multi-cast optical switches and tunable optical demultiplexers and multiplexers illustrated in FIG. 6 are controlled in response to an optical service channel present on the input optical communication path 312-1, for example. As noted above, the demultiplexer 360 selects the optical service channel from the input optical communication path 360 and supplies the optical service channel to the control circuit 350. The optical service channel is converted to electrical signals by the control circuit 350 and control signals are generated that are used to control the tunable elements 624, 626, 628, 630, 632, and 634, for example.

As further illustrated in FIG. 6, the multi-cast optical switch 634 may be used to couple any add port to any WSS output optical communication path. For example, optical signals supplied to the add ports from the tunable transmitters 697-1 to 697-n (it should be understood that similar transmitters are coupled to the add ports of the tunable optical multiplexer 632, as well as any other tunable optical multiplexer coupled to the multi-cast optical switch 634) or inputs of the tunable optical multiplexer or combiner 630 are combined and supplied to the input 634-1 of the multi-cast optical switch 634. If desired, the multi-cast optical switch 634 may direct those optical signals to a particular output, e.g. the output 634-6. From there, the optical signals pass through the splitter 690-6, optional optical amplifier 640-2, and dispersion compensating element 638-2. The optical signals are next combined with the output signals from the WSS 315 onto the output optical communication path 313-2 by the combiner 320-2. Alternatively, these optical signals could be supplied to other output optical communication paths through one or more other outputs 634-5 to 634-n of the multi-cast optical switch 634, and corresponding ones of the splitters 690-5 to 690-n, optional optical amplifiers 640-1 to 640-n, dispersion compensating elements 638-1 to 638-n, and combiners 320-1 to 320-n. In a similar fashion, the multi-cast optical switch 634 may couple other tunable optical multiplexers or combiners, such as the tunable optical multiplexer 632, to any one of the output optical communication paths 313-1 to 313-n, or be combined with the output from the tunable optical multiplexer 630 and supplied to any desired output optical communication path.

In accordance with a further aspect of the present invention, the splitter 612-1 may be provided with a supplemental output or expansion port 612-20 not connected to the multi-cast switch 624, but for coupling to an additional multi-cast optical switch, if necessary. Moreover, the multi-cast optical switches 624 and 634 may also include a supplemental output 624-6 and supplemental input 634-2, respectively, also for expansion purposes. Further, the combiner 690-5 includes a supplemental input 604 not coupled to the multi-cast switch 634, but included for coupling to additional multi-cast optical switches, as dictated by system and capacity requirements.

The optical add/drop multiplexer illustrated in FIG. 6 advantageously may provide 1+1 protection. For example, the input optical communication path 312-1 may serve as a working path, while input the input optical communication path 312-2 may serve as a protection path. During normal operation, information carried by the working path 312-1 may be directed by the multi-cast switch 624 toward the receiver circuit 696-1. In response to a fault on the working path 312-1, the multi-cast switch 624 (which can also constitute an L×M switch, where L and M do not necessarily have the same value) may route signals originating from the input optical path 312-2, the protection path, to the output 624-5 and to the tunable demultiplexer 626, which itself may be controlled to select the desired optical signals. Such rerouting may be achieved in less than 2 msec, thereby effectively realizing a 1+1 protection scheme.

Protection schemes may also be realized on the add side. For example, the optical signals originating from the tunable optical transmitter 697-1 may be directed toward a working output optical communication path 313-1 by the multi-cast switch 634 through the output 634-5 to the combiner 690-5, optional dispersion compensating element 638-1, optional optical amplifier 640-1, and combiner 320-1. In response to a fault on the optical communication path 313-1, optical signals from transmitter 697-1 may be rerouted by the multi-cast optical witch 634 to be supplied through the output 634-6 to the output optical communication path (a protection path) via the combiner 690-6, optional amplifier 640-2, optional dispersion compensating element 638-2, and combiner 320-2. By facilitating the use of both working and protection paths, 1+1 and 1:N protection schemes may be achieved.

Again, ROADMs are the key technology for the next generation of DWDM systems. These ROADMs allow for the automated rearrangement of wavelengths of light on the multichannel optical fibers entering and leaving optical network nodes. For a high-degree optical network node, with a degree number of up to 8, for example, directionless ROADMs are preferred because they may route any wavelength of light on any optical fiber (or from any direction) to any given transceiver entirely in the optical domain.

Several architectures have been proposed for directionless ROADMs, including the incorporation of a power splitter followed by a receiver with a tunable selector, which is one of the more promising designs that supports full-flexibility directionless add/drop in a modular approach. This architecture is described in U.S. Pat. No. 7,308,197, the contents of which are incorporated in full by reference herein which is based on N×M multi-cast switches 710 and 720, as is illustrated in FIGS. 7( a) and 7(b).

Referring to FIGS. 7( a) and 7(b), the key enabler for this architecture is to have a directionless signal distribution module that is powered by its N×M multi-cast switches 710 and 720 for dynamic optical signal rerouting without wavelength or direction constraints. This signal distribution module has N inputs 711-1 to 711-n from N ports 713-1 to 713-n and M outputs 712-1 to 712-m and a tunable receiver 714 equipped with a tunable filter (not illustrated) that is utilized to select the exact wavelength for drop (see FIG. 7( a)) A similar design is implemented at the add side (see FIG. 7( b)), with a tunable transmitter 724 equipped with a tunable filter (not illustrated) that is utilized to select the exact wavelength for add and M inputs 721-1 to 721-m and N outputs 722-1 to 722-n to N ports 723-1 to 723-n.

In general, there are two types of N×M multi-cast switches. Type A is realized through PLC technology by cascading 2×2 thermo-optic Mach-Zehnder switches 810 in an N×M configuration (see FIG. 8( a)), which has been disclosed by Infineon and Lynx Photonics in 2000 and 2001, for example. In this configuration, signals experience different insertion losses (ILs) under different splitting conditions, where extra variable optical attenuator (VOA) stages are normally built in at the output side to balance the output optical power per channel (or per wavelength). Other PLC vendors, such as NEL, for example, can build this type of N×M multi-cast switches by modifying their current N×N optical switch matrices. Type BN×M multi-cast switches are achieved by connecting discrete N1×M splitter arrays 820 and MN×1 switch arrays 822, as illustrated in FIG. 8( b). The MN×1 switch arrays 822 may be based on any technology, including three-dimensional (3D) micro-electromechanical system (MEMS) technology. In most designs, type BN×M multi-cast switches utilize a fixed splitter at the front end, such that all of the optical paths have the same ILs. Advanced technologies may be utilized to manufacture tunable splitters as well, and manufacture type BN×M multi-cast switches having similar functions as type AN×M multi-cast switches, such as type B+ N×M multi-cast switches. Enablence is a vendor of such components, for example.

Referring to FIG. 9, the ILs introduced by optical power splitting through either a fixed power splitting ratio in type BN×M multi-cast switches or a reconfigurable power splitting ratio in type A or type B+ multi-cast switches may be compensated for utilizing EDFAs 920-1, 920-2, and 920-n arranged in an array and coupled to the N×M multi-cast switch 910.

Type B multi-cast switches with fixed power splitting ratios have fixed ILs for all of the associated optical communication paths that are relatively easy to manage with a conventional EDFA array, which is normally running in a constant gain or constant power mode. In order to ensure the per channel optical power output of the N×M multi-cast switch 910 meeting certain power level specifications, each EDFA 920-1, 920-2, and 920-n of the EDFA array should be powerful enough to cover the large ILs of the type BN×M multi-cast switch. It will be readily apparent to those of ordinary skill in the art that type A multi-cast switches may also be used in this design, but the IL for each optical communication path varies from configuration to configuration, unless VOAs are used to balance this power variation.

On the other hand, silica-based PLCs have been implemented in EDFA design for several years because of their superior stability, high reliability, and impressive flexibility. Recently, JDS Uniphase has built a three-stage erbium amplifier prototype using a PLC chip that includes 980 nm/1550 nm WDMs, fixed ratio taps, variable optical attenuators, and a 980 nm pump laser/tunable splitter. The use of a tunable splitter allowed the pump laser to be operated more efficiently and inexpensively. This type of design does not provide significant cost advantages for a single EDFA, but it is feasible to build smaller size and lower cost EDFA arrays (see, e.g. U.S. Pat. No. 6,980,576).

FIG. 10 is a schematic diagram illustrating a design utilizing four EDFAs 1010 arranged in an array 1020 and using 1×4 tunable splitters 1030. The EDFA array 1020 may share up to four pumps 1040, for example, to maximize the output power. The 1×4 tunable splitters may be integrated with other components, such as VOAs and 980 nm/1550 nm WDMs, for example. This concept may be extended to an array of eight EDFAs, etc.

Again, in existing ROADM designs, EDFA arrays with fixed gains or output powers are utilized in order to satisfy a worst case scenario, even though there are only M (e.g. 8 or 16) channels to be dropped for a given modular design. This is not a cost effective solution. Each EDFA is over designed to support the worst case scenario, when all of the wavelengths of light or channels are fully populated. More than 40% of the associated cost is attributed to the pump lasers for the individual EDFAs. In order to simplify the design of the signal distribution modules utilized in directionless ROADM applications, as well as shrink their size and lower their cost, the present invention provides a novel configuration that takes full advantage of type A/type B+ N×M multi-cast switches and the advanced EDFA array design with PLC-based tunable pump splitters.

Referring to FIG. 11, signal distribution module 1100 of the present invention includes an EDFA array 1110 incorporating N EDFAs 1110-1, 1110-2, 1110-3, and 1110-n coupled to N inputs 1112-1, 1112-2, 1112-3, and 1112-n of an N×M multi-cast switch 1120 including M outputs 1122-1 to 1122-m, as well as to a shared pump laser 1130 and a 1×N tunable splitter, in order to accommodate the variable ILs of the N×M multi-cast switch 1120. For example, as illustrated in FIG. 11, a 4×8 multi-cast switch 1120 is configured as a 1×4 splitter for input port 1 1112-1 (with 6 dB theoretical splitting loss) and a 1×3 splitter for input port 2 1112-2 (with 5 dB theoretical splitting loss), with no connection for input port 3 1112-3 and a one-to-one connection for input port 4 1112-n (with 0 dB theoretical splitting loss). In this configuration, different amounts of the pump laser signal may be delivered to each EDFA 1110-1, 1110-2, 1110-3, and 1110-n—50% to EDFA 1 1110-1, 40% to EDFA 2 1110-2, none to EDFA 3 1110-3, and 10% to EDFA 4 1110-n. Thus, the following may be achieved: 6 dBm total output power from EDFA 1 1110-1, 5 dBm total output power from EDFA 2 1110-2, no light from EDFA 3 1110-3, and 0 dBm total output power from EDFA 4 1110-n. After the 4×8 multi-cast switch 1130, an equal power of −3 dBm is observed at all the output ports 1122-1 to 1122-m (assuming a 3 dB intrinsic IL for each of the switches).

The signal distribution module of the present invention represents an ideal solution for directionless ROADM applications as it represents a low cost, compact, low power consumption assembly. For example, up to an 8-channel drop may be realized on a single one-slot card.

Referring to FIG. 12, in an exemplary embodiment, a typical implementation for a directionless add/drop module 1200 as described herein includes a “drop” side 1202 and an “add” side 1204 with three major parts: EDFAs 1206, N×M multi-cast switches 1208, and tunable filters 1210. At the “drop” side 1202, the 4×8 multi-cast switches 1208 are used to deliver the function of all directing wavelengths from any direction to any transceiver, where the tunable filter 1210 at each output of multi-cast switches 1208 is used to select the specific wavelength channel to the receiver. The EDFAs 1206 are needed to compensate the insertion loss (IL) of multi-cast switches 1208 and tunable filters 1210. Similarly, at the “add” side 1204, the 4×8 multi-cast switches 1208 are used to combine the output signal from any transmitter at any wavelength to specific direction, where the tunable filter 1210 at the input of the multi-cast switches 1208 is used to limit the bandwidth of high speed signals and to suppress out-of-band ASE. Again, the EDFAs 1206 are used to compensate the insertion loss of multi-cast switches 1208 and tunable filters 1210.

At the drop side 1202, in order to support only eight-channel drop, the four EDFAs 1206 in the typical implementation have to achieve very high output powers considering the amplification of all WDM channels, making this design extreme low efficiency in term of EDFA usage. U.S. patent application Ser. No. 12/268,817, filed on Nov. 11, 2008, and entitled “SIGNAL DISTRIBUTION MODULE FOR A DIRECTIONLESS RECONFIGURABLE OPTICAL ADD/DROP MULTIPLEXER” (the parent case of this application), proposes a novel pump-sharing solution to reduce the total pump power requirements. However, this scheme requires fast transient control. Secondly, since there will be a large scale combiner (e.g., 1×12 combiner) in typical “add” design to combine all the signals from each directionless add/drop module, the accumulation of amplified stimulated emission (ASE) which is generated by those “add” EDFAs 1206 could result in large optical signal-to-noise ratio (OSNR) penalties, particularly when those EDFAs 1206 are running at high gain with low input powers. Additionally, the EDFAs 1206 will require transient control if they are implemented at the output side of multi-cast switches 1208, making it difficult to do pump sharing.

Referring to FIGS. 13 a-13 b, in an exemplary embodiment, the add side 1204 in the directionless add/drop module 1200 of FIG. 12 is illustrated with different placements of the EDFAs 1206. Specifically, FIG. 13 a illustrates placement of the EDFAs 1206 prior to the tunable filters 1210, and FIG. 13 b illustrates placement of the EDFAs 1206 between the tunable filters 1210 and the multicast switch 1208. Note, in FIG. 12, the add side 1204 includes the EDFAs 1206 after the multicast switch. Advantageously, the exemplary embodiments in FIGS. 13 a-13 b include improved the OSNR at the add side 1204 and reduced complexity of pump laser control (associated with the EDFAs 1206). Though it requires four more sets of EDFA passive components, it could improve the OSNR by more than 10 dB and require just one shared pump laser among the EDFAs 1206.

Referring to FIGS. 14 a-14 b, in an exemplary embodiment, the drop side 1202 in the directionless add/drop module 1200 of FIG. 12 is illustrated with distributed gain. Advantageously, the exemplary embodiments of FIGS. 14 a-14 b cut the number of pump lasers and reduce total power consumption at the drop side 1202 utilizing distributed gain. The distributed gain is achieved using two-stages of EDFAs 1410, 1420 at both the input and output side of multi-cast switches 1208. The second stage EDFAs can be put after the tunable filters 1210 as illustrated in FIG. 14 a, or between a mid-stage of tunable filters 1430, 1440 as illustrated in FIG. 14 b. Clearly, these second stage 8-channel EDFA 1410, 1420 arrays have no transient control requirements and can share a small pump laser. Though it may require more EDFA passive components, it significantly reduces the output power requirements for the first stage EDFAs 1410, and effectively reduces the total power consumption and cost.

Referring to FIG. 15, in an exemplary embodiment, the drop side 1202 in the directionless add/drop module 1200 of FIG. 12 is illustrated with channel selective filters 1510. The channel selective filters 1510 may be a reconfigurable blocking filter (RBF), also known as wavelength blocker, or the like. Here, the channel selective filters 1510 filter out unneeded wavelengths thereby reducing the associated power consumption of the EDFAs 1206. Specifically, with only up to eight channels to be amplified for each “drop” EDFA 1206, pump power requirements are reduced dramatically, i.e. the channel selective filters 1510 block all but eight channels.

Referring to FIGS. 16 a-16 b, in an exemplary embodiment, a bi-directional design 1600 is illustrated for the directionless add/drop module 1200 of FIG. 12. FIGS. 16 a-16 b illustrate the bi-directional design 1600 with respect to the drop side 1202 in the directionless add/drop module 1200 of FIG. 12. FIG. 16 a illustrates the embodiment of FIG. 14 b utilizing the bi-directional design 1600 for “drop” with distributed gain. FIG. 16 b illustrates the embodiment of FIG. 15 with the bi-directional design 1600 for “drop” with channel selective filters 1510. To achieve the bi-directional design 1600, a pair of circulators 1610, 1620 is on either side of the multi-cast switch 1208. In FIG. 16 a, the circulators 1610 are disposed between the EDFAs 1410 and the multi-cast switch 1208 and the circulators 1620 are disposed between the first set of tunable filters 1430 and the EDFAs 1420. In FIG. 16 b, the circulators 1610 are disposed between the EDFAs 1206 and the multi-cast switch 1208, and the circulators 1620 are disposed between the tunable filters 1210 and drop/add ports.

Referring to FIGS. 17 a-17 b, in an exemplary embodiment, an integrated design directionless add/drop module 1700 is illustrated with a broadcast and select architecture. Specifically, FIG. 17 a illustrates an integrated drop side 1702 and FIG. 17 b illustrates an integrated add side 1704. Advantageously, the integrated design directionless add/drop module 1700 provides smaller size and power consumption than the other embodiments described herein. In this approach, the multicast switch 1208 is replaced is replaced by amplifier arrays 1710, splitters 1720, and combiners 1730. In FIG. 17 a, the drop side 1702 includes splitters 1720 receiving input signals of a plurality of wavelengths. The splitters 1720 split out specific wavelengths that are then filtered to a single wavelength or group of wavelengths through the tunable filters 1740. The amplifier array 1710 is configured to amplify the output of each of the tunable filters 1740. The amplifier array 1710 may include semiconductor optical amplifiers (SOAs) or the like. Outputs from each of the splitters 1720 are connected to each of the combiners 1730 through the intermediate tunable filters 1740 and the amplifier array 1710. The combiners 1730 combine each of the inputs and include tunable filters 1750 on the output to filter or select a desired wavelength. In the integrated design directionless add/drop module 1700, to connect a particular transceiver to a particular degree, the amplifier 1710 in the path between the degree input/output and the transceiver is turned on, while the amplifiers 1710 connecting the transceiver to other degrees are turned off. In FIG. 17 b, the add side 1704 includes splitters 1720 receiving an input signal and splits the input to each of the amplifiers in the amplifier array 1710. The amplifier array 1710 connects to the tunable filters 1740 which in turn connect to the combiners 1730 which combine the outputs of the tunable filters 1740.

Although the present invention has been illustrated and described herein with reference to preferred embodiments and specific examples thereof, it will be readily apparent to those of ordinary skill in the art that other embodiments and examples may perform similar functions and/or achieve like results. All such equivalent embodiments and examples are within the spirit and scope of the present invention, are contemplated thereby, and are intended to be covered by the following claims. 

1. An add side of a directionless optical add/drop module, comprising: a multi-cast switch having a plurality of input ports and a plurality of output ports; a plurality of optical amplifiers connected to the plurality of input ports of the multi-cast switch, wherein the plurality of optical amplifiers form an optical amplifier array; and a plurality of tunable filters connected to the plurality of input ports of the multi-cast switch.
 2. The add side of claim 1, wherein the plurality of tunable filters disposed between the plurality of input ports of the multi-cast switch and the plurality of optical amplifiers.
 3. The add side of claim 1, wherein the plurality of optical disposed between the plurality of input ports of the multi-cast switch and the amplifiers plurality of tunable filters.
 4. The add side of claim 1, wherein the plurality of optical amplifiers comprise a plurality of erbium-doped fiber amplifiers, and wherein the plurality of erbium-doped fiber amplifiers form an erbium-doped fiber amplifier array.
 5. The add side of claim 4, wherein the erbium-doped fiber amplifier array utilizes a shared pump laser.
 6. A drop side of a directionless optical add/drop module, comprising: a multi-cast switch having a plurality of input ports and a plurality of output ports; a plurality of optical amplifiers connected to the plurality of input ports of the multi-cast switch, wherein the plurality of optical amplifiers form an optical amplifier array; and a plurality of tunable filters connected to the plurality of output ports of the multi-cast switch.
 7. The drop side of claim 6, wherein the plurality of optical amplifiers comprises a plurality of erbium-doped fiber amplifiers, and wherein the plurality of erbium-doped fiber amplifiers forms an erbium-doped fiber amplifier array.
 8. The add side of claim 7, wherein the erbium-doped fiber amplifier array utilizes a shared pump laser.
 9. The drop side of claim 6, further comprising: a second plurality of optical amplifiers connected to the plurality of output ports of the multi-cast switch, wherein the second plurality of optical amplifiers form a second optical amplifier array, and wherein the optical amplifier array and the second optical amplifier array are configured to provide distributed gain.
 10. The drop side of claim 9, wherein the second optical amplifier array is disposed between the multi-cast switch and the plurality of tunable filters.
 11. The drop side of claim 9, wherein the plurality of tunable filters comprise a first plurality of tunable filters and a second plurality of tunable filters, and wherein the second optical amplifier array is disposed between the first plurality of tunable filters and the second plurality of tunable filters.
 12. The drop side of claim 11, further comprising: a first plurality of optical circulators connected between the optical amplifier array and the multi-cast switch; and a second plurality of optical circulators connected between the first plurality of tunable filters and the second optical amplifier array.
 13. The drop side of claim 6, further comprising: a plurality of channel selective filters connected to inputs of the optical amplifier array.
 14. The drop side of claim 13, further comprising: a first plurality of optical circulators connected between the optical amplifier array and the multi-cast switch; and a second plurality of optical circulators connected to outputs of the plurality of tunable filters.
 15. An integrated directionless optical add/drop module, comprising: a drop side comprising a broadcast and select architecture; and an add side comprising the broadcast and select architecture; wherein the broadcast and select architecture comprises turning an amplifier on in a path to connect a particular transceiver to a particular degree while also turning a plurality of amplifiers connecting the transceiver to other degrees off.
 16. The integrated directionless optical add/drop module of claim 15, wherein the drop side and the add side comprise a plurality of splitters, a plurality of combiners, a plurality of tunable filters, and a plurality of optical amplifiers.
 17. The integrated directionless optical add/drop module of claim 16, wherein the drop side comprises the plurality of splitters connected to the plurality of tunable filters, the tunable filters connected to the plurality of optical amplifiers, the plurality of optical amplifiers connected to the plurality of combiners, and a second plurality of tunable filters connected to outputs of the plurality of combiners; and wherein the add side comprises the plurality of splitters connected to the plurality of optical amplifiers, the plurality of optical amplifiers connected to the plurality of tunable filters, and the plurality of tunable filters connected to the plurality of combiners.
 18. The integrated directionless optical add/drop module of claim 16, wherein the plurality of optical amplifiers comprise an amplifier array of semiconductor optical amplifiers. 